Abstract: Various examples with respect to dual threshold clock control are described. A method involves sensing an input voltage of a processing circuit with a first mechanism and a second mechanism different from the first mechanism. The method also involves regulating a first droop of the input voltage using the first mechanism. The method further involves regulating a subsequent droop of the input voltage after the first droop using the second mechanism.

Abstract: A method of detecting and preventing over current induced system failure is provided. An OC protect controller monitors a CPU total power consumption based on received CPU activity information. In response to the monitoring, if the CPU power consumption is over a threshold, then the OC protect controller outputs a frequency dithering control signal to reduce the CPU clock frequency such that the CPU does not reach an OC limit. The OC protect controller also outputs a PLL frequency control signal to reduce the PLL clock frequency to improve system efficiency.

Abstract: A method of detecting and preventing over current induced system failure is provided. An OC protect controller monitors a CPU total power consumption based on received CPU activity information. In response to the monitoring, if the CPU power consumption is over a threshold, then the OC protect controller outputs a frequency dithering control signal to reduce the CPU clock frequency such that the CPU does not reach an OC limit. The OC protect controller also outputs a PLL frequency control signal to reduce the PLL clock frequency to improve system efficiency.

Abstract: A method is provided that includes performing a free placement of a system design comprising a plurality of power domains, wherein the power domains are not constrained to physical regions, assigning a physical region to each of the power domains based on the free placement of cells in the power domains, performing a soft cluster placement of the system design with each power domain and corresponding physical region defined as a soft cluster, refining at least one physical region based on the soft cluster placement, redefining cells in at least one power domain based on the soft cluster placement of the cells and the corresponding physical region, and performing a hard cluster placement of the system design with each power domain and corresponding physical region defined as a hard cluster to generate final power domains.

Abstract: A method is provided that includes performing a free placement of a system design comprising a plurality of power domains, wherein the power domains are not constrained to physical regions, assigning a physical region to each of the power domains based on the free placement of cells in the power domains, performing a soft cluster placement of the system design with each power domain and corresponding physical region defined as a soft cluster, refining at least one physical region based on the soft cluster placement, redefining cells in at least one power domain based on the soft cluster placement of the cells and the corresponding physical region, and performing a hard cluster placement of the system design with each power domain and corresponding physical region defined as a hard cluster to generate final power domains.

Abstract: System and method for reducing power-on transient current magnitude on distributed header switches. A preferred embodiment comprises a distributed header switch coupling a circuit to a power supply, the distributed header switch comprising a linear sequence of combination switches, each combination switches containing a pre-charge switch and a header switch. A first-pass involves sequentially turning on each of the pre-charge switches, which enables a voltage level at the distributed header switch to approach that of a final voltage level and a second-pass involves sequentially turning on each of the header switches. Since the voltage level at the distributed header switches is close to the final voltage level, a resulting transient current is small in magnitude.

Abstract: An integrated circuit. The integrated circuit comprises an area having a layout aligned in rows. Each row is definable by a pair of row boundaries. The integrated circuit also comprises a plurality of cells, comprising a first set of cells. Each cell in the first set of cells spans at least two rows and comprises a PMOS transistor having a source/drain region that spans across one of the row boundaries and an NMOS transistor having a source/drain region that spans across one of the row boundaries.

Abstract: An integrated circuit. The integrated circuit comprises an area having a layout aligned in rows. Each row is definable by a pair of row boundaries. The integrated circuit also comprises a plurality of cells, comprising a first set of cells. Each cell in the first set of cells spans at least two rows and comprises a PMOS transistor having a source/drain region that spans across one of the row boundaries and an NMOS transistor having a source/drain region that spans across one of the row boundaries.

Abstract: System and method for providing power with a large on-current and small off-current to circuitry in an integrated circuit. A preferred embodiment comprises a switch for providing power to circuits in an integrated circuit made from a PMOS transistor and an NMOS transistor coupled in parallel. Each transistor's gate terminal is coupled to a separate control signal line. The PMOS transistor provides current to the circuits at high voltage supply levels while the NMOS transistor provides current to the circuits at low voltage supply levels, wherein the size of the PMOS and NMOS transistor can be changed during design to meet power requirements. Depending upon power requirements, multiple PMOS and NMOS transistors may be used. The combination of PMOS and NMOS transistors permit the use of limited fabrication processes wherein transistor widths can be limited.

Abstract: System and method for reducing power-on transient current magnitude on distributed header switches. A preferred embodiment comprises a distributed header switch coupling a circuit to a power supply, the distributed header switch comprising a linear sequence of combination switches, each combination switches containing a pre-charge switch and a header switch. A first-pass involves sequentially turning on each of the pre-charge switches, which enables a voltage level at the distributed header switch to approach that of a final voltage level and a second-pass involves sequentially turning on each of the header switches. Since the voltage level at the distributed header switches is close to the final voltage level, a resulting transient current is small in magnitude.

Abstract: System and method for providing power with a large on-current and small off-current to circuitry in an integrated circuit. A preferred embodiment comprises a switch for providing power to circuits in an integrated circuit made from a PMOS transistor and an NMOS transistor coupled in parallel. Each transistor's gate terminal is coupled to a separate control signal line. The PMOS transistor provides current to the circuits at high voltage supply levels while the NMOS transistor provides current to the circuits at low voltage supply levels, wherein the size of the PMOS and NMOS transistor can be changed during design to meet power requirements. Depending upon power requirements, multiple PMOS and NMOS transistors may be used. The combination of PMOS and NMOS transistors permit the use of limited fabrication processes wherein transistor widths can be limited.

Abstract: System and method for reducing power-on transient current magnitude on distributed header switches. A preferred embodiment comprises a distributed header switch coupling a circuit to a power supply, the distributed header switch comprising a linear sequence of combination switches, each combination switches containing a pre-charge switch and a header switch. A first-pass involves sequentially turning on each of the pre-charge switches, which enables a voltage level at the distributed header switch to approach that of a final voltage level and a second-pass involves sequentially turning on each of the header switches. Since the voltage level at the distributed header switches is close to the final voltage level, a resulting transient current is small in magnitude.

Abstract: System and method for reducing power-on transient current magnitude on distributed header switches. A preferred embodiment comprises a distributed header switch coupling a circuit to a power supply, the distributed header switch comprising a linear sequence of combination switches, each combination switches containing a pre-charge switch and a header switch. A first-pass involves sequentially turning on each of the pre-charge switches, which enables a voltage level at the distributed header switch to approach that of a final voltage level and a second-pass involves sequentially turning on each of the header switches. Since the voltage level at the distributed header switches is close to the final voltage level, a resulting transient current is small in magnitude.

Abstract: System and method for providing power with a large on-current and small off-current to circuitry in an integrated circuit. A preferred embodiment comprises a switch for providing power to circuits in an integrated circuit made from a PMOS transistor and an NMOS transistor coupled in parallel. Each transistor's gate terminal is coupled to a separate control signal line. The PMOS transistor provides current to the circuits at high voltage supply levels while the NMOS transistor provides current to the circuits at low voltage supply levels, wherein the size of the PMOS and NMOS transistor can be changed during design to meet power requirements. Depending upon power requirements, multiple PMOS and NMOS transistors may be used. The combination of PMOS and NMOS transistors permit the use of limited fabrication processes wherein transistor widths can be limited.

Abstract: A method of expanding data to a high-speed serial video link in such a way that it is invisible to existing receivers and such that auxiliary data, i.e. audio data, can be transmitted without any knowledge of the capabilities of the display to receive the auxiliary data.

Abstract: An encoding scheme simplifies the TMDS encoding algorithm described in the DVI 1.0 specification while retaining compatibility with most existing DVI receivers. The generation of the Transition Control bit has been removed; and although the INV bit has a similar function to the DC bit in the DVI 1.0 standard, the algorithm for deriving it is very different. No attempt is made to maintain a DC balance on the cable. Instead, the INV bit is set to a ‘1’ for the purpose of removing ‘rogue’ character sequences; otherwise it is always set to a ‘0’.

Abstract: A predriver for a differential pair having a reduce voltage swing is disclosed having fast switching speed and low power consumption. The predriver includes a p-type MOS transistor, and a first and second n-type MOS transistor. The source of the p-type MOS couples to the first power supply rail. The gate of the first n-type MOS transistor couples to the gate of the p-type MOS transistor to form an input. The drain of the first n-type MOS transistor couples to the drain of the p-type MOS transistor to form an output. The drain of the second n-type MOS transistor couples to the source of the first n-type MOS transistor. The source of the second n-type MOS transistor couples to ground. The gate of the second n-type MOS transistor couples to the output. The presence of the second n-type MOS transistor alters the voltage swing of the predriver to be from the threshold voltage level to the full power supply voltage, substantially reducing the current or power consumption.

Abstract: An encoding scheme simplifies the TMDS encoding algorithm described in the DVI 1.0 specification while retaining compatibility with most existing DVI receivers. The generation of the Transition Control bit has been removed; and although the INV bit has a similar function to the DC bit in the DVI 1.0 standard, the algorithm for deriving it is very different. No attempt is made to maintain a DC balance on the cable. Instead, the INV bit is set to a ‘1’ for the purpose of removing ‘rogue’ character sequences; otherwise it is always set to a ‘0’.

Abstract: A predriver for a differential pair having a reduce voltage swing is disclosed having fast switching speed and low power consumption. The predriver includes a p-type MOS transistor, and a first and second n-type MOS transistor. The source of the p-type MOS couples to the first power supply rail. The gate of the first n-type MOS transistor couples to the gate of the p-type MOS transistor to form an input. The drain of the first n-type MOS transistor couples to the drain of the p-type MOS transistor to form an output. The drain of the second n-type MOS transistor couples to the source of the first n-type MOS transistor. The source of the second n-type MOS transistor couples to ground. The gate of the second n-type MOS transistor couples to the output. The presence of the second n-type MOS transistor alters the voltage swing of the predriver to be from the threshold voltage level to the full power supply voltage, substantially reducing the current or power consumption.

Abstract: A method of expanding data to a high-speed serial video link in such a way that it is invisible to existing receivers and such that auxiliary data, i.e. audio data, can be transmitted without any knowledge of the capabilities of the display to receive the auxiliary data.